Hydrogen Bonding Versus van der Waals Interactions: Competitive Influence of Noncovalent Interactions on 2D Self‐Assembly at the Liquid–Solid Interface

Mali, Kunal S.; Lava, Kathleen; Binnemans, Koen; Feyter, Steven De

doi:10.1002/chem.201001653

Cited by 93 publications

(94 citation statements)

References 84 publications

(148 reference statements)

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“…In addition, two-dimensional crystallization energy resulting from van der Waals forces between long alkyl chains can induce full interdigitation of alkyl chains and leads to the densely packed lamellar structures on surfaces [18]. Owing to the inherent conformation flexibility of alkyl chains, the interesting structural evolution of functional molecule homologues decorated with alkyl chains with different lengths has been observed in a number of systems [13][14][15][16].…”

Section: Introductionmentioning

confidence: 99%

“…Non-covalent bond interactions between molecules are mainly responsible for the formation of perfectly ordered supramolecular structures on surfaces [13][14][15]. Non-covalent bond interactions, for instance van der Waals forces [16][17][18][19][20], hydrogen bonds [21][22][23][24], π -π stacking interactions [25,26], dipole-dipole interactions [27][28][29] and electrostatic interactions [30,31] between functional groups in organic molecules, play an important role in the self-assembly process.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Two-dimensional self-assemblies of telechelic organic compounds: structure and surface host–guest chemistry

Yan

Liu

Wang

et al. 2013

Phil. Trans. R. Soc. A.

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Guiding the self-assembly of different types of functional molecules into well-defined structures on surfaces is beneficial for both fundamental surface and interface study and emerging application fields, especially molecular and organic electronics. This review focuses on understanding the two-dimensional self-assembly process of telechelic organics, which feature alkoxylene chains terminated with carboxyl groups. With the combined flexibility of alkyl chains and directionality of carboxyl groups, telechelic organics show unique assembly behaviour on two-dimensional surfaces. By increasing the length of the alkoxylene chains, the cavities in the nanoporous networks of telechelic trimesic acid (1,3,5-benzene tricarboxylic acid) derivatives change from hexagonal cavities to irregular cavities on a highly oriented pyrolytic graphite surface. The nanoporous networks provide a flexible host template for host–guest supramolecular chemistry because the cavities framed by the flexible alkoxylene chains can be changed in accordance with the sizes/shapes of the guest molecules. Furthermore, the terminal carboxylic group can form a hydrogen bond with another hydrogen bond partner, leading to multi-component structural motifs and hierarchical assemblies. The unique assembly behaviour of telechelic organics makes them promising structures as important building blocks for the design and construction of complex self-assembled nanoarchitectures.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Two-dimensional self-assemblies of telechelic organic compounds: structure and surface host–guest chemistry

Yan

Liu

Wang

et al. 2013

Phil. Trans. R. Soc. A.

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“…This attractive interaction is negligible compared to the interaction between the functional groups. Examples of such systems include adsorption layers of alkoxybenzoic acids, 59 mono-functional derivatives of anthracene, 61 porphyrin and phthalocyanine. 12,19,20,[62][63][64][65] As seen in Fig.…”

Section: Effect Of the Chemical Structure Of The Adsorbing Moleculementioning

confidence: 99%

“…The size of the functional groups and side substituents of the adsorbed molecule is either smaller than or commensurate with the size of their cores. Examples of such systems include the adsorption layers of amino acids, 7,23,58 alkoxybenzoic acids, 59 functional derivatives of benzene, 23 naphthalene and other bicyclic and more complicated organic molecules 22,23,60 such as anthracene, 61 porphyrin and phthalocyanine. 12,19,20,[62][63][64][65] It is important to stress that all the above mentioned molecules have a single functional group capable of forming a hydrogen bond.…”

Section: Model and Simulation Techniquesmentioning

confidence: 99%

Cross-impact of surface and interaction anisotropy in the self-assembly of organic adsorption monolayers: a Monte Carlo and transfer-matrix study

Горбунов

Akimenko

Myshlyavtsev

2017

Phys. Chem. Chem. Phys.

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abUsing a simple lattice gas model we study the features of self-assembly in adsorption layers where both ''molecule-surface'' and ''molecule-molecule'' interactions are anisotropic. Based on the example of adsorption layers of mono-functional organic molecules on the heterogeneous surface with strip-like topography, we have revealed plenty of possible self-assembled structures in this simple system, such as discrete, linear, zigzag, chess board-like, two-dimensional porous and close-packed patterns. However, the phase behavior of the adsorption layer is much richer, if the interactions between functional and non-functional parts of adjacent adsorbed molecules have comparable strength and opposite signs. It is demonstrated that filling of the strips composed of relatively ''strong'' adsorption sites with the increase of chemical potential can be non-monotonic. This effect is associated with surface anisotropy and results from the changing of the driving force of the self-assembly process -interactions between the adsorbed molecule and the surface dominate at low surface coverages, but intermolecular forces prevail at higher ones. Additionally, when the width of the strip composed of ''strong'' adsorption sites is two or more times greater than that of the adsorbed molecule, a local assembly of the ordered phases on the ''strong'' adsorption sites is observed. Our results suggest strategies for controlling the self-assembly in experiments involving mono-functional organic molecules on a strip-like heterogeneous surface.

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“…10 In particular, by confining the selfassembly process on solid substrates, two-dimensional (2D) structures can be formed 11,12 by exploiting a number of different intermolecular forces: from metal coordination 13,14 to hydrogen bonding 14,15 , to weaker dispersion interactions. 16 While the nature of the interactions between the molecular units is typically the key factor in determining the resulting assembly, other more subtle influences have also been reported to affect the final supramolecular structures: the chemistry and symmetry of the substrate (even for inert surfaces such as highly ordered pyrolytic graphite (HOPG) and Au(111) 17 ), the temperature, [18][19][20] the ultra-high vacuum (UHV) or solution environment, 19,21,22 the nature of the solvent, 19,[23][24][25][26][27][28] the concentration of the solute (the self-assembling molecule), 18,[29][30][31][32][33][34][35] and any co-adsorption of solvent or guest molecules 24,25,34,36,37 . The possibility of controlling supramolecular polymorphism by weak intermolecular interactions, such as interactions with the solvent, is a new and fascinating approach to the ultimate goal of rationally programming molecular self-assembly.…”

Section: Introductionmentioning

confidence: 99%

Molecular self-assembly of substituted terephthalic acids at the liquid/solid interface: investigating the effect of solvent

et al. 2017

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Self-assembly of three related molecules – terephthalic acid and its hydroxylated analogues – at liquid/solid interfaces (graphite/heptanoic acid and graphite/1-phenyloctane) has been studied using a combination of scanning tunnelling microscopy and molecular mechanics and molecular dynamics calculations. Brickwork-like patterns typical for terephthalic acid self-assembly have been observed for all three molecules. However, several differences became apparent: (i) formation or lack of adsorbed monolayers (self-assembled monolayers formed in all systems, with one notable exception of terephthalic acid at the graphite/1-phenyloctane interface where no adsorption was observed), (ii) the size of adsorbate islands (large islands at the interface with heptanoic acid and smaller ones at the interface with 1-phenyloctane), and (iii) polymorphism of the hydroxylated terephthalic acids’ monolayers, dependent on the molecular structure and/or solvent. To rationalise this behaviour, molecular mechanics and molecular dynamics calculations have been performed, to analyse the three key aspects of the energetics of self-assembly: intermolecular, substrate–adsorbate and solvent–solute interactions. These energetic characteristics of self-assembly were brought together in a Born–Haber cycle, to obtain the overall energy effects of formation of self-assembled monolayers at these liquid/solid interfaces.

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Hydrogen Bonding Versus van der Waals Interactions: Competitive Influence of Noncovalent Interactions on 2D Self‐Assembly at the Liquid–Solid Interface

Cited by 93 publications

References 84 publications

Two-dimensional self-assemblies of telechelic organic compounds: structure and surface host–guest chemistry

Two-dimensional self-assemblies of telechelic organic compounds: structure and surface host–guest chemistry

Cross-impact of surface and interaction anisotropy in the self-assembly of organic adsorption monolayers: a Monte Carlo and transfer-matrix study

Molecular self-assembly of substituted terephthalic acids at the liquid/solid interface: investigating the effect of solvent

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